Uplink control channel resource determination method, terminal, and network side device

ABSTRACT

An uplink control channel resource determination method, a terminal, and a network side device are provided, relating to the field of wireless communications. The terminal determines the number N of bits of the uplink control information to be transmitted; the terminal determines, according to a target coding rate and N, the number of first resources; the terminal determines, according to the number of first resources and the number of pre-configured resources, the number of resources actually used; and the terminal uses the number of resources actually used to transmit the uplink control information.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a 371 application of International Application No. PCT/CN2018/114309, filed on Nov. 7, 2018, which claims priority to International Application No. PCT/CN2017/110255, filed on Nov. 9, 2017, the entire disclosures of both of which are hereby incorporated by reference in their entireties.

TECHNICAL FIELD

The present disclosure relates to the field of wireless communication, and more particular, to technologies for determining uplink control channel resources.

BACKGROUND

In order to ensure the demodulation performance of uplink control channels in a 5G New Radio (NR) system, a network device may configure respectively the maximum code rate of uplink control information being able to be carried for different terminals (the lower a code rate is, the larger a corresponding uplink coverage radius is, and the lower a probability that the terminal transmission power is limited).

In addition, it is determined in the NR that a resource corresponding to an uplink control channel for transmitting feedback response information is jointly indicated through a higher layer signaling and a dynamic signaling by a base station. That is, a plurality of available resources (time domain, frequency domain, code domain) are preconfigured through a higher layer signaling, and a dynamic signaling indicates one of them for actual transmission. Since a time/frequency domain size of a resource is semi-statically configured by a higher layer signaling, the flexibility is limited. When a value range of a size of uplink control information (UCI) actually transmitted is very large, transmission of the UCI using a preconfigured resource may cause a resource waste, i.e. when UCI bits are few, many frequency domain resources (PRBs) and/or time domain resources (symbols) are still occupied for transmission.

SUMMARY

A purpose of the present disclosure is to provide a method for determining uplink control channel resources, a terminal, and a network side device.

In order to solve the problem, the present disclosure discloses a method for determining uplink control channel resources, including: determining, by a terminal, that a first quantity of resources as a quantity of resources to be actually used when the first quantity of resources is less than or equal to a quantity of preconfigured resources, wherein the first quantity of resources is determined based on a quantity N of bits of uplink control information to be transmitted and a target code rate; determining, by the terminal, that the quantity of the resources to be actually used is the quantity of the preconfigured resources when the first quantity of resources is greater than the quantity of the preconfigured resources; and transmitting, by the terminal, uplink control information using the quantity of the resources to be actually used.

In one implementation, when the quantity of the resources to be actually used is the first quantity of resources, the resources to be actually used are first Q resources of the preconfigured resources and the Q is the first quantity of resources.

In one implementation, the method further includes: determining, by the terminal, the quantity N of bits of the uplink control information to be transmitted.

In one implementation, the target code rate is configured by a network side device.

In one implementation, the quantity of the preconfigured resources includes: a quantity of frequency domain resource blocks occupied by an uplink control channel; or a quantity of resource elements occupied by an uplink control channel.

In one implementation, the quantity of the preconfigured resources is determined by one of the following manners: indicating through a higher layer signaling; or preconfiguring at least one available resource through a higher layer signaling, and indicating one of the at least one available resource through downlink control information.

The present disclosure further discloses a method for determining uplink control channel resources, including: determining, by a network side device, that a first quantity of resources as a quantity of resources to be actually used when the first quantity of resources is less than or equal to a quantity of preconfigured resources, wherein the first quantity of resources is determined based on a quantity N of bits of uplink control information to be received and a target code rate; determining, by the network side device, that the quantity of the resources to be actually used is the quantity of the preconfigured resources when the first quantity of resources is greater than the quantity of the preconfigured resources; and receiving, by the network side device, uplink control information using the quantity of the resources to be actually used.

In one implementation, when the quantity of the resources to be actually used is the first quantity of resources, the resources to be actually used are first Q resources of the preconfigured resources and the Q is the first quantity of resources.

The present disclosure discloses a terminal, including: a practical resource quantity determination module, used for determining that a first quantity of resources as a quantity of resources to be actually used when the first quantity of resources is less than or equal to a quantity of preconfigured resources, wherein the first quantity of resources is determined based on a quantity N of bits of uplink control information to be transmitted and a target code rate; and determining that the quantity of the resources to be actually used is the quantity of the preconfigured resources when the first quantity of resources is greater than the quantity of the preconfigured resources; and a transmission module, used for transmitting uplink control information by using the quantity of the resources to be actually used.

In one implementation, when the quantity of the resources to be actually used is the first quantity of resources, the resources to be actually used are first Q resources of the preconfigured resources and the Q is the first quantity of resources.

In one implementation, the terminal further includes: a signaling bit quantity determination module, used for determining a quantity N of bits of the uplink control information to be transmitted.

The present disclosure discloses a network side device, which includes: a practical resource quantification module, used for determining that a first quantity of resources as a quantity of resources to be actually used when the first quantity of resources is less than or equal to a quantity of preconfigured resources, wherein the first quantity of resources is determined based on a quantity N of bits of uplink control information to be received and a target code rate; and determining that the quantity of the resources to be actually used is the quantity of the preconfigured resources when the first quantity of resources is greater than the quantity of the preconfigured resources; and a receiving module, used for receiving uplink control information using the quantity of the resources to be actually used.

In one implementation, when the quantity of the resources to be actually used is the first quantity of resources, the resources to be actually used are first Q resources of the preconfigured resources and the Q is the first quantity of resources.

A terminal provided by the example of the present disclosure includes a processor and a memory, wherein the memory is used for storing a computer program, and the processor is used for calling and executing the computer program stored in the memory to execute the method for determining uplink control channel resources.

A network side device provided by the example of the present disclosure includes a processor and a memory, wherein the memory is used for storing a computer program; and the processor is used for calling and executing the computer program stored in the memory to execute the method for determining uplink control channel resources.

A computer readable storage medium provided by the example of the present disclosure is used for storing a computer program that causes a computer to execute the method for determining uplink control channel resources.

A large number of technical features are recorded in the specification of the present disclosure and distributed in various technical solutions. If all possible combinations of technical features (i.e. technical solutions) of the present disclosure are listed, the specification will be too lengthy. In order to avoid the problem, various technical features disclosed in the summary of the present disclosure, various technical features disclosed in the following implementations and examples, and various technical features disclosed in the drawings may be freely combined with each other to form various new technical solutions (all of which are deemed to have been recorded in the specification), unless such combination of technical features is not technically feasible. For example, if feature A+B+C is disclosed in one example, feature A+B+D+E is disclosed in another example, and features C and D are equivalent technical means that play the same role, and technically, one of C and D may be chosen and C and D cannot be used at the same time, and feature E may be technically combined with feature C, then the solution of A+B+C+D should not be considered as already recorded because of technical infeasibility, while the solution of A+B+C+E should be considered as already recorded.

BRIEF DESCRIPTION OF DRAWINGS

The drawings described herein are used to provide a further understanding of the present disclosure and form a part of the present disclosure. Illustrative examples of the present disclosure and the description thereof are used to explain the present disclosure and do not constitute improper limitation of the present disclosure. In the drawings:

FIG. 1 is a flowchart of a method for determining uplink control channel resources in a first implementation of the present disclosure.

FIG. 2 is a flowchart of a method for determining uplink control channel resources in a second implementation of the present disclosure.

DETAILED DESCRIPTION

In the following description, many technical details are set forth in order to enable readers to better understand the present disclosure. However, one of ordinary skill in the art may understand that technical solutions claimed in the present disclosure may be realized even without these technical details and various variations and modifications based on the following implementations.

Description of some concepts is as follows.

5G: 5th Generation Mobile Communication Technology.

NR: Radio Access Part of 5G (5th Generation Mobile Communication Technology), abbreviation for New Radio.

PUCCH: abbreviation for Physical Uplink Control Channel.

SR: uplink Scheduling Request, abbreviation for Scheduling Request.

OFDM: abbreviation for Orthogonal Frequency Division Multiplexing.

UCI: abbreviation for Uplink control information.

PRB: abbreviation for Physical Resource Block.

The following outlines some of innovations of the present disclosure.

A terminal determines a first quantity of resources according to a quantity N of bits of uplink control information to be transmitted and a target code rate, and if the first quantity of resources is less than or equal to a quantity of preconfigured resources, the first quantity of resources is used as a quantity of resources to be actually used to transmit the N-bit uplink control information. If the first quantity of resources is greater than the quantity of the preconfigured resources, then an upper limit of a quantity of bits of uplink control information allowed to be transmitted by the quantity of the preconfigured resources is determined. According to the upper limit and the target code rate, the quantity T of bits of the uplink control information to be transmitted (at this time, a specific content of the uplink control information is also changed correspondingly) is re-determined by means of signaling compression, etc. (a specific manner of signaling compression is not limited in the present disclosure). Then, the previous N is replaced by the T and the method is iterated to finally determine the quantity of the resources to be actually used. In this way, a problem of resource waste caused by mismatch between a semi-statically determined quantity of pre-configured resources and the quantity of the resources actually used is avoided.

The above contents are only some innovations of the present disclosure, and other innovations and many variations are described in detail in the following implementations.

In order to make objects, technical solutions, and advantages of the present disclosure clearer, the implementations of the present disclosure will be described in further detail below with reference to the accompanying drawings.

A first implementation of the present disclosure relates to a method for determining uplink control channel resources. FIG. 1 is a flowchart of the method for determining uplink control channel resources. The method for determining uplink control channel resources includes acts 101-104.

In act 101, a terminal determines a quantity N of bits of uplink control information to be transmitted, wherein N is a positive integer.

After that, entering act 102, the terminal determines a first quantity of resources according to a target code rate and N. In at least one implementation, the target code rate may be configured by the network side device. In at least one implementation, the target code rate may be predetermined according to a protocol.

After that, entering act 103, the terminal determines a quantity of resources to be actually used and uplink control information to be actually transmitted according to the first quantity of resources and the quantity of the preconfigured resources, wherein the quantity of the resources to be actually used is less than or equal to the quantity of the preconfigured resources and a quantity of bits of uplink control information to be actually transmitted is less than or equal to N. The act of determining the uplink control information to be actually transmitted is optional, or in other words, only the quantity of the resources to be actually used may be determined, and the uplink control information to be actually transmitted may be the uplink control information to be transmitted without re-determination.

After that, entering act 104, the terminal transmits uplink control information using the quantity of the resources to be actually used. In at least one implementation, what is to be actually transmitted is uplink control information to be transmitted initially. In at least one implementation, what is to be actually transmitted is new uplink control information after a processing such as signaling compression.

When a value range of a size of UCI actually transmitted is very large, the problem of waste of time-frequency resources may be effectively prevented.

Terminals may be various, such as smart phones, tablet computers, desktop computers, notebook computers, customized wireless terminals, Internet of Things nodes, wireless communication modules, etc., as long as wireless communication may be performed with a network side according to an agreed communication protocol.

There are many possibilities for the quantity of the preconfigured resources and the first quantity of resources, for example, a quantity of frequency domain resource blocks occupied by an uplink control channel, a quantity of resource elements occupied by an uplink control channel, etc.

There are many ways for determining the quantity of the preconfigured resources, for example, indicating through a higher layer signaling; or, preconfiguring at least one available resource through a higher layer signaling, and indicating one of the at least one available resource through downlink control information.

The act 103 may be implemented in various ways. The following are examples.

In at least one implementation, when the first quantity of resources is less than or equal to the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the first quantity of resources (assuming that the first quantity of resources is Q), wherein the resources to be actually used may be first Q resources, last Q resources, or Q resources in other agreed positions of the preconfigured resources, etc.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. At this time, the uplink control information to be transmitted (i.e., the N-bit uplink control information to be transmitted in the act 101) is transmitted in the act 104.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the terminal determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. Signaling compression needs to be performed on the uplink control information to be transmitted to obtain new uplink control information to be transmitted, and a quantity of bits of the new uplink control information to be transmitted is less than or equal to the first quantity of bits of the uplink control information. The quantity of the resources to be actually used is equal to the quantity of the preconfigured resources.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the terminal determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. Signaling compression needs to be performed on the uplink control information to be transmitted to obtain new uplink control information to be transmitted, and a quantity of bits of the new uplink control information to be transmitted is less than or equal to the first quantity of bits of the uplink control information. Further, replacing a position of N in the act 101 with the quantity T of bits of the new uplink control information to be transmitted, the entire flow returns from the act 103 to the act 101. The terminal determines a second quantity of resources according to the target code rate and the quantity of bits of the new uplink control information to be transmitted. The quantity of the resources to be actually used is equal to the second quantity of resources. The transmitted uplink control information is the new uplink control information to be transmitted.

In order to explain the implementation more clearly and in detail, several specific examples are described below.

Example one: the terminal determines that a target code rate is r_(max)=½, and a quantity N of bits of uplink control information to be transmitted is equal to 8. The quantity of the preconfigured resources is 2 PRBs (each PRB includes 12 carriers). The terminal uses 2 symbols of PUCCH to transmit uplink control information (i.e. occupying 2 time domain symbols), wherein overhead of reference signals contained in the PUCCH is ⅓, and the PUCCH adopts QPSK modulation, and a corresponding modulation level Q is equal to 2.

The terminal determines that the first quantity of resources is

${\left\lceil \frac{N}{r_{m\;{ax}} \cdot Q \cdot N_{{UCI}\;\_\;{RE}}} \right\rceil = {\left\lceil \frac{8}{{1/2} \cdot 2 \cdot \left( {12 \cdot 2 \cdot {2/3}} \right)} \right\rceil = 1}},$ wherein N_(UCI_RE) is a quantity of REs occupied by UCI in a PRB.

The first quantity of resources is less than the quantity of the preconfigured resources, and the terminal determines to transmit the uplink control information using one PRB.

Example two: the terminal determines that a target code rate is r_(max)=⅛, and a quantity N of bits of uplink control information to be transmitted is equal to 10. The quantity of the preconfigured resources is 2 PRBs (each PRB includes 12 carriers). The terminal uses 2 symbols of PUCCH to transmit uplink control information (i.e. occupying 2 time domain symbols), wherein overhead of reference signals contained in the PUCCH is ⅓, and the PUCCH adopts QPSK modulation, and a corresponding modulation level Q is equal to 2.

The terminal determines that the first quantity of resources is

${\left\lceil \frac{N}{r_{{ma}\; x} \cdot Q \cdot N_{{UCI}\;\_\;{RE}}} \right\rceil = {\left\lceil \frac{10}{{1/8} \cdot 2 \cdot \left( {12 \cdot 2 \cdot {2/3}} \right)} \right\rceil = 3}},$ wherein N_(UCI_RE) is a quantity of REs occupied by UCI in a PRB.

The first quantity of resources is greater than the quantity of the preconfigured resources, and the terminal determines that the first quantity of bits of the uplink control information is T=└r_(max)·Q·N_(UCI_RE)·N_(configured)┘=└⅛·2·(12·2·⅔)·2┘=8, wherein N_(configured) is the quantity of the preconfigured resources.

The terminal compresses the bits of the uplink control information to be transmitted to obtain new uplink control information to be transmitted, of which a quantity of bits is less than or equal to 8. The terminal transmits the new uplink control information to be transmitted.

Example three: based on the Example two, if due to limitation of UCI compression manner, the terminal determines that a quantity of bits of uplink control information to be actually transmitted is T<└r_(mac)·Q·N_(UCI_RE)·N_(configured)┘, and it is assumed that T=4.

The terminal further determines a quantity of resources actually needed to transmit the 4-bit uplink control information

${\left\lceil \frac{N}{r_{{ma}\; x} \cdot Q \cdot N_{{UCI}\;\_\;{RE}}} \right\rceil = {\left\lceil \frac{4}{{1/8} \cdot 2 \cdot \left( {12 \cdot 2 \cdot {2/3}} \right)} \right\rceil = 1}}.$

The terminal determines to use one PRB to transmit the 4-bit compressed uplink control information.

A second implementation of the present disclosure relates to a method for determining uplink control channel resources.

The first implementation is a method at a terminal side for determining uplink control channel resources, and the second implementation is a method at a network side for determining uplink control channel resources. Technical concepts of the two implementations are the same, but locations of the implementations are different, and relevant details may be used interchangeably. FIG. 2 is a flowchart of the method for determining uplink control channel resources.

In act 201, a network side device determines a quantity N of bits of uplink control information to be received, wherein N is a positive integer.

After that, entering act 202, the network side device determines a first quantity of resources according to a target code rate and N. In at least one implementation, the target code rate may be configured by the network side device. In at least one implementation, the target code rate may be predetermined according to a protocol.

After that, entering act 203, the network side device determines a quantity of resources to be actually used according to the first quantity of resources and a quantity of preconfigured resources, wherein the quantity of the resources to be actually used is less than or equal to the quantity of the preconfigured resources.

After that, entering act 204, the network side device receives uplink control information using the quantity of the resources to be actually used.

There are many possibilities for the quantity of the preconfigured resources and the first quantity of resources, for example, a quantity of frequency domain resource blocks occupied by an uplink control channel, a quantity of resource elements occupied by an uplink control channel, etc.

There are many ways for determining the quantity of the preconfigured resources, for example, indicating through a higher layer signaling; or, preconfiguring at least one available resource through a higher layer signaling, and indicating one of the at least one available resource through downlink control information.

The act 203 may be implemented in various ways. The following are examples.

In at least one implementation, when the first quantity of resources is less than or equal to the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the first quantity of resources (assuming that the first quantity of resources is Q), wherein the resources to be actually used may be first Q resources, last Q resources, or Q resources in other agreed positions of the preconfigured resources, etc.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. In this case, in the act 204, what is actually received is uplink control information of N bits.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the network side device determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. The quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. In this case, in the act 204, what is actually received is uplink control information after signaling compression.

In at least one implementation, when the first quantity of resources is greater than the quantity of the preconfigured resources, the network side device determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. The network side device determines a second quantity of resources according to the target code rate and a quantity of bits of new uplink control information to be received, wherein the new uplink control information to be received is obtained after signaling compression is performed on the uplink control information to be received, and the quantity of bits of the new uplink control information to be received is less than or equal to the first quantity of bits of the uplink control information. The quantity of the resources to be actually used is equal to the second quantity of resources. In this case, actually iteration is performed by returning to the act 201 according to the quantity of bits (replacing N in the act 201) of the new uplink control information to be received after signaling compression.

A third implementation of the present disclosure relates to a terminal. The terminal includes following modules.

A signaling bit quantity determination module is used for determining a quantity N of bits of uplink control information to be transmitted.

A first quantity of resources determination module is used for determining a first quantity of resources according to a target code rate and N. In at least one implementation, the target code rate may be configured by the network side device. In at least one implementation, the target code rate may be predetermined according to a protocol.

A practical resource quantity determination module is used for determining a quantity of resources to be actually used and uplink control information to be actually transmitted according to the first quantity of resources and a quantity of preconfigured resources, wherein the quantity of the resources to be actually used is less than or equal to the quantity of the preconfigured resources and a quantity of bits of the uplink control information to be actually transmitted is less than or equal to N. The determination for the uplink control information to be actually transmitted is optional.

A signaling compression module is used for performing signaling compression on the uplink control information to be transmitted to obtain new uplink control information to be transmitted. The signaling compression module is optional.

A transmission module is used for transmitting uplink control information by using the quantity of the resources to be actually used. In at least one implementation, what is actually transmitted is uplink control information to be transmitted initially. In at least one implementation, what is actually transmitted is new uplink control information after a processing such as signaling compression.

There are many possibilities for the quantity of the preconfigured resources and the first quantity of resources, for example, a quantity of frequency domain resource blocks occupied by an uplink control channel, a quantity of resource elements occupied by an uplink control channel, etc.

There are many ways for determining the quantity of the preconfigured resources, for example, indicating through a higher layer signaling; or, preconfiguring at least one available resource through a higher layer signaling, and indicating one of the at least one available resource through downlink control information.

The practical resource quantity determination module has many ways for implementation, and the following are examples.

In at least one implementation, when the practical resource quantity determination module determines that the first quantity of resources is less than or equal to the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the first quantity of resources (assuming that the first quantity of resources is Q), wherein the resources to be actually used may be first Q resources, last Q resources, or Q resources in other agreed positions of the preconfigured resources, etc.

In at least one implementation, when the practical resource quantity determination module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. In this case, what the transmission module transmits is the uplink control information to be transmitted.

In at least one implementation, when the practical resource quantity determination module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, the terminal determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. In this case, the signaling compression module performs signaling compression on the uplink control information to be transmitted to obtain the new uplink control information to be transmitted, wherein a quantity of bits of the new uplink control information to be transmitted is less than or equal to the first quantity of bits of the uplink control information. The quantity of the resources to be actually used is equal to the quantity of the preconfigured resources.

In at least one implementation, when the practical resource quantity determination module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, the terminal determines a first quantity of bits of uplink control information according to the target code rate and the quantity of the preconfigured resources. In this case, the signaling compression module performs signaling compression on the uplink control information to be transmitted to obtain the new uplink control information to be transmitted, wherein a quantity of bits of the new uplink control information to be transmitted is less than or equal to the first quantity of bits of the uplink control information. The terminal determines a second quantity of resources according to the target code rate and the quantity of bits of the new uplink control information to be transmitted. The quantity of the resources to be actually used is equal to the second quantity of resources. The uplink control information transmitted by the transmission module is the new uplink control information to be transmitted.

The first implementation is a method implementation corresponding to the implementation, and the implementation may be implemented in cooperation with the first implementation. The relevant technical details mentioned in the first implementation are still valid in the implementation, and will not be repeated here in order to reduce repetition. Correspondingly, the relevant technical details mentioned in the implementation may be applied in the first implementation.

A fourth implementation of the present disclosure relates to a network side device. The network side device includes following modules.

A signaling bit quantification module is used for determining the quantity N of bits of the uplink control information to be received.

A first resource quantification module is used for determining a first quantity of resources according to a target code rate and N. In at least one implementation, the target code rate may be configured by the network side device. In at least one implementation, the target code rate may be predetermined according to a protocol.

A practical resource quantification module is used for determining a quantity of resources to be actually used according to the first quantity of resources and a quantity of preconfigured resources, wherein the quantity of the resources to be actually used is less than or equal to the quantity of the preconfigured resources.

A receiving module is used for receiving uplink control information through the quantity of the resources to be actually used.

There are many possibilities for the quantity of the preconfigured resources and the first quantity of resources, for example, a quantity of frequency domain resource blocks occupied by an uplink control channel, a quantity of resource elements occupied by an uplink control channel, etc.

There are many ways for determining the quantity of the preconfigured resources, for example, indicating through a higher layer signaling; or, preconfiguring at least one available resource through a higher layer signaling, and indicating one of the at least one available resource through downlink control information.

The practical resource quantification module has many ways for implementation. The following are examples.

In at least one implementation, when the practical resource quantitative module determines that the first quantity of resources is less than or equal to the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the first quantity of resources (assuming that the first quantity of resources is Q), wherein the resources to be actually used may be first Q resources, last Q resources, or Q resources in other agreed positions of the preconfigured resources, etc.

In at least one implementation, when the practical resource quantification module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, the quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. In this case, what the receiving module actually receives is the uplink control information (of N bits) to be received.

In at least one implementation, when the practical resource quantification module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, a first quantity of bits of uplink control information is determined according to the target code rate and the quantity of the preconfigured resources. The quantity of the resources to be actually used is equal to the quantity of the preconfigured resources. In this case, what the receiving module actually receives is uplink control information after signaling compression.

In at least one implementation, when the practical resource quantification module determines that the first quantity of resources is greater than the quantity of the preconfigured resources, a first quantity of bits of uplink control information is determined according to the target code rate and the quantity of the preconfigured resources. A second quantity of resources is determined according to the target code rate and a quantity of bits of new uplink control information to be received, wherein the new uplink control information to be received is obtained after signaling compression is performed on the uplink control information to be received, and the quantity of bits of the new uplink control information to be received is less than or equal to the first quantity of bits of the uplink control information. The quantity of the resources to be actually used is equal to the second quantity of resources. In this case, what the receiving module actually receives is uplink control information after signaling compression.

The second implementation is a method implementation corresponding to the implementation, and the implementation may be implemented in cooperation with the second implementation. The relevant technical details mentioned in the second implementation are still valid in the implementation, and will not be repeated here in order to reduce repetition. Correspondingly, the relevant technical details mentioned in the implementation may be applied in the second implementation.

Various method implementations of the present disclosure may be implemented in software, hardware, firmware, etc. Whether the present disclosure is implemented in software, hardware or firmware, codes of instructions may be stored in any type of computer accessible memory (e.g., permanent or modifiable, volatile or nonvolatile, solid or non-solid, fixed or replaceable medium). Similarly, the memory may be, for example, a Programmable Array Logic (PAL), a Random Access Memory (RAM), a Programmable Read Only Memory (PROM), a Read-Only Memory (ROM), an electrically erasable programmable ROM (EEPROM), a magnetic disk, an optical disk, or a Digital Versatile Disc (DVD).

It should be noted that various units mentioned in various device implementations of the present disclosure are logical units. Physically, a logical unit may be a physical unit, a part of a physical unit, or a combination of multiple physical units. Physical implementations of these logical units are not the most important. A combination of functions implemented by these logical units is a key to solving the technical problem raised by the present disclosure. In addition, in order to highlight innovative parts of the present disclosure, the device implementations of the present disclosure do not introduce units that are not closely related to solving the technical problem raised by the present disclosure, which does not mean that there are no other units in the device implementations.

It should be noted that in the present disclosure documents of the patent, relational terms such as first and second etc. are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Moreover, the terms “include”, “contain” or any other variation thereof are intended to cover a non-exclusive inclusion, such that a process, method, article, or device that includes a list of elements not only includes those elements but also includes other elements not expressly listed, or further includes elements inherent to such process, method, article, or device. Without further restrictions, an element defined by a statement “include one” does not exclude presence of another identical element in the process, method, article or device that includes the element. In the present disclosure document of the patent, if it is mentioned that an act is executed according to an element, it means that the act is executed according to at least the element, which includes two cases: the act is executed only according to the element, and the act is executed according to the element and another element. Multiple, multiple times, multiple types and other expressions include two, two times, two types, two or more, two times or more, two types or more.

All documents mentioned in the present disclosure are hereby incorporated by reference as if each document is individually incorporated by reference. In addition, it should be understood that after reading the teachings of the present disclosure, those skilled in the art may make various variations or modifications to the present disclosure, and these equivalent forms also fall within the scope of protection claimed in the present disclosure. 

What is claimed is:
 1. A method for determining physical uplink control channel (PUCCH) resources, comprising: when a first quantity of physical resource blocks (PRBs) is less than or equal to a quantity of preconfigured PRBs, determining, by a terminal, the first quantity of PRBs as a quantity of PRBs to be actually used, wherein the first quantity of PRBs is determined based on and a target code rate, and N is a quantity of bits of uplink control information to be transmitted; and transmitting, by the terminal, the uplink control information using the first quantity of PRBs; and when the first quantity of PRBs is greater than the quantity of the preconfigured PRBs, performing, by the terminal, signaling compression on the uplink control information to obtain new uplink control information to be transmitted, wherein a quantity of bits of the new uplink control information to be transmitted is less than or equal to a first quantity of bits of the uplink control information, the first quantity of bits of the uplink control information is determined according to the target code rate and the quantity of the preconfigured PRBs, a second quantity of PRBs is the quantity of the PRBs to be actually used, and the second quantity of PRBs is determined according to the target code rate and the quantity of bits of the new uplink control information to be transmitted; and transmitting, by the terminal, all bits of the new uplink control information using the second quantity of PRBs.
 2. The method according to claim 1, wherein when the quantity of the PRBs to be actually used is the first quantity of PRBs, the PRBs to be actually used are first Q PRBs of the preconfigured PRBs and the Q is the first quantity of PRBs.
 3. The method according to claim 2, wherein the target code rate is configured by a network side device.
 4. The method according to claim 2, wherein the quantity of the preconfigured PRBs comprises: a quantity of frequency domain PRB s occupied by an uplink control channel; or a quantity of PRB elements occupied by the uplink control channel.
 5. The method according to claim 2, wherein the quantity of the preconfigured PRBs is determined by one of the following manners: indicating through higher layer signaling; or preconfiguring at least one available PRB through the higher layer signaling, and indicating one of the at least one available PRB through downlink control information.
 6. A non-transitory computer readable storage medium storing a computer program, wherein the computer program causes a computer to perform the method according to claim
 1. 7. The method according to claim 1, wherein the target code rate is configured by a network side device.
 8. The method according to claim 1, wherein the quantity of the preconfigured PRBs comprises: a quantity of frequency domain PRBs occupied by an uplink control channel; or a quantity of PRB elements occupied by the uplink control channel.
 9. The method according to claim 1, wherein the quantity of the preconfigured PRBs is determined by one of the following manners: indicating through a higher layer signaling; or preconfiguring at least one available PRB through the higher layer signaling, and indicating one of the at least one available PRB through downlink control information.
 10. The method according to claim 1, wherein a quantity of bits of the uplink control information to be actually transmitted is less than or equal to the N.
 11. The method according to claim 2, wherein a quantity of bits of the uplink control information to be actually transmitted is less than or equal to the N.
 12. A method for determining physical uplink control channel (PUCCH) resources, comprising: when a first quantity of physical resource blocks (PRBs) is less than or equal to a quantity of preconfigured PRBs, determining, by a network side device, the first quantity of PRBs as a quantity of PRBs to be actually used, wherein the first quantity of PRB s is determined based on N and a target code rate, and N is a quantity of bits of uplink control information to be received; and receiving, by the network side device, the uplink control information using the first quantity of PRBs; and when the first quantity of PRB s is greater than the quantity of the preconfigured PRBs, receiving, by the network side device using a second quantity of PRBs, all bits of new uplink control information that is obtained after signaling compression is performed on the uplink control information to be received, wherein a quantity of bits of the new uplink control information is less than or equal to a first quantity of bits of the uplink control information, the first quantity of bits of the uplink control information is determined according to the target code rate and the quantity of the preconfigured PRBs, the second quantity of PRBs is the quantity of the PRBs to be actually used, and the second quantity of PRBs is determined according to the target code rate and the quantity of bits of the new uplink control information.
 13. The method according to claim 12, wherein when the quantity of the PRBs to be actually used is the first quantity of PRBs, the PRBs to be actually used are first Q PRBs of the preconfigured PRBs and the Q is the first quantity of PRBs.
 14. A non-transitory computer readable storage medium storing a computer program, wherein the computer program causes a computer to perform the method according to claim
 12. 15. A terminal for determining physical uplink control channel (PUCCH) resources, comprising: a processor and a memory, wherein the memory is configured to store a computer program and the processor is configured to call and execute the computer program stored in the memory to perform the following acts: when a first quantity of physical resource blocks (PRBs) is less than or equal to a quantity of preconfigured PRBs, determining the first quantity of PRBs as a quantity of PRBs to be actually used, wherein the first quantity of PRB s is determined based on a N and a target code rate, and N is a quantity of bits of uplink control information to be transmitted; and transmitting the uplink control information using the first quantity of PRBs; and when the first quantity of PRB s is greater than the quantity of the preconfigured PRBs, performing signaling compression on the uplink control information to be transmitted to obtain new uplink control information, wherein a quantity of bits of the new uplink control information to be transmitted is less than or equal to a first quantity of bits of the uplink control information, the first quantity of bits of the uplink control information is determined according to the target code rate and the quantity of the preconfigured PRBs, a second quantity of PRBs is the quantity of the PRBs to be actually used, and the second quantity of PRBs is determined according to the target code rate and the quantity of bits of the new uplink control information to be transmitted; and transmitting all bits of the new uplink control information using the second quantity of PRBs.
 16. The terminal according to claim 15, wherein when the quantity of the PRBs to be actually used is the first quantity of PRBs, the PRBs to be actually used are first Q PRBs of the preconfigured PRBs and the Q is the first quantity of PRBs.
 17. The terminal according to claim 15, wherein a quantity of bits of the uplink control information to be actually transmitted is less than or equal to the N.
 18. The terminal according to claim 16, wherein a quantity of bits of the uplink control information to be actually transmitted is less than or equal to the N.
 19. A network side device for determining physical uplink control channel (PUCCH) resources, comprising: a processor and a memory, wherein the memory is configured to store a computer program and the processor is configured to call and execute the computer program stored in the memory to perform the following acts: when a first quantity of physical resource blocks (PRBs) is less than or equal to a quantity of preconfigured PRBs, determining the first quantity of PRBs as a quantity of PRBs to be actually used, wherein the first quantity of PRBs is determined based on N and a target code rate, and N is a quantity of bits of uplink control information to be received; and receiving the uplink control information using the first quantity of PRBs; and when the first quantity of PRBs is greater than the quantity of the preconfigured PRBs, by using a second quantity of PRBs, receiving all bits of new uplink control information that is obtained after signaling compression is performed on the uplink control information to be received, wherein a quantity of bits of the new uplink control information is less than or equal to a first quantity of bits of the uplink control information, the first quantity of bits of the uplink control information is determined according to the target code rate and the quantity of the preconfigured PRBs, the second quantity of PRBs is the quantity of the PRBs to be actually used, and the second quantity of PRB s is determined according to the target code rate and the quantity of bits of the new uplink control information.
 20. The network side device according to claim 19, wherein when the quantity of the PRBs to be actually used is the first quantity of PRBs, the PRBs to be actually used are first Q PRBs of the preconfigured PRBs and the Q is the first quantity of PRBs. 